Impact welder



g. 28, 1945. R, S THACKER 2,383,695

IMPACT WELDER Original Filed May 28, 1940 4 Sheets-Sheet 1 ,Pefssaef lNvENTOR Fa/,o/l 5I Thacker BY M ATTORNEY Aug. 28, 1945. R, s THACKER 2,383,695

IMPAGT WELDER Original Filed May 28, 1940 4 Sheets-Sheet 2 ATTORNEY Aug. 28, 1945. R. s. THAcKx-:R 2,383,595

IMPACT wELnEa Original Filed May 28, 1940 4 Sheets-Sheet 3 45 Til.

IN v E NTOR 9o/p 5. 7770069'- 4 v BYM/ nd ATToRN EY Aug. 2s, 1945. R s THACKER 2,333,695

IIPACT WELDER Original Filed May 28, 1940 4 Sheets-Sheet 4 'A-[TORNNEY V Patented Aug. 28, 19.45

nuPAoT wELnEa Ralph S. Thacker, West Los Angeles, Calif., as-

signor to Leo M. Harvey, La Canada,` Calif.

Original application May 28, 1940, Serial No.

337,638. Divided and this application 24, 1942, Serial No. 456,122

l1 Claims.

This invention relates to the art of welding, and particularly to one in which the parts to be welded together are subjected to a forging pressure. This application is a division of an application entitled Impact welding, filed in the name of Ralph S. Thacker, on May 28, 1940, un-

der Serial No. 337,638 now Patent No. 2,305,042.

granted December l5., 1942. l

In general the' art of joining two metals together while they are heated to a plastic condition by forging or hammering is old; but the equipment required for this old process is cumbersome and heavy, and the operation is necessarily slow. It is one of the objects of this invention to make 1t possible rapidly to produce such welds with simple apparatus, either stationary or portable, and without the exercise of any uncommo'n degree of skill.

It is another object of this invention to make it possible to utilize electrical energy for heating those portions 'of the pieces of metal which are to be welded together; and particularly by the passage of current between the pieces.

In order to attain these objects, a particular cycle of operations is provided, which is initiated at will bythe operator. and which can be repeated in Vrapid succession as often as required.

It is thus another object'of this invention to pro-` `vide an apparatus capable of accomplishing these functions. This cycle includes the step of rst applying a moderate pressure between the pieces to be welded, so as to ensure continuity in the path for the heating current to be passed through the contacting surfaces, and of such order that the current encounters sufficient resistance rapidly to cause the pieces in the vicinity of the pres- ,sure application to become plastic or molten.

After this pressure is attained, the pieces are heated by the passage of an electric heating current, and simultaneously the pressure is increased.

' This causes more intimate contact between the pieces, and a consequent decrease of resistance causing a tapering olf of the heating.

Then the heating current is disconnected and the pressure is yet maintained or increased even after the current ow ceases. The adjoining parts are then forced together during the period that the plastic areas congeal.

If it is desired to obtain a more severe mechanical working for securing a better grairi structure, a hammer blow may be used on the pieces in the weld area immediately after the plastic area is congealed.

It is accordingly a further object of this inven- August (Cl. 21S-4) ytion to make it possible expeditiously to complete a cycle as described; and especially by operating a control mechanism that automatically causes the desired sequence of steps.

5 'I'his invention possesses many other advantages, and has'other objects which may be made.

purpose there are shown a few forms in the drawings accompanying and forming part of the-present specication. These forms will now be described in detail, illustrating the general principles of the invention; but it is to be understood that this detailed description is not to be taken illustrated in Fig. 3;

Fig. 5 is a View similar to Fig. 3 of a modied form of the apparatus; and

Fig. 6 is an enlarged fragmentary section of a portion of the apparatus illustrated in Fig. 3.

The two pieces to be joined by impact welding in accordance with the invention are illustrated as flat plates I and 2 (Figs. 1 and 3). These plates may be of weldable metal, such as steel or iron. In order to obtain a weld, an electrode structure 3 is arranged t be pressed against the piece I for conducting a heating current through the contacting surface of pieces I and 2. The current and resistance which is determined by pressure are of such values to produce sulcient heat to cause a pool 4 of molten or plastic metal to form. This pool is intersected at the contacting surfaces 5. In Fig. l, a source 6 of low potential heating current is indicated, connected to the electrode structure 3 and to the lower plate 2.

The heating of the metal in this manner is Fig, 4 is a schematic diagram of the apparatus mediate portion of the period during which pressure is applied. The pressure gradually builds up so as to produce proper admixture of the plastic metal forming pool 4, and is applied with continually greater force even after the current is stopped. This results in an impact weld, for as the pool 4 cools, the pressure ensures intimate union of the pieces I and 2 by the aid of the coalesced metal that forms the plastic pool 4.

Furthermore, if desired, at the conclusion of the pressure increasing cycle, a hammer blow may be exerted upon the electrode l for further intensive working of the metal t produce the desired grain structure in the weld. l

This system of welding is indicated graphically in Fig. 2, where the abscissae of the graph represent time; and the ordinates represent pressure as applied between the plates I and 2. During the iirst period, the pressure builds up continuously from a low value to a point corresponding to the ordinate of point 1. At this point the heating current is applied. This heating current is continued until the point 8 is reached. At the same time the pressure is continuously increased, corresponding to the ordinate of the point 8. Thereafter, at the conclusion of the application of the heating current, there is a holding pressure which continuously increases to a value corresponding to the ordinate of point 9. During the application of this holding pressure the metal of pool 4 congeals. At the conclusion of the gradual increase of pressure, a violent hammer blow may be struck, corresponding to a pressure represented'by the ordinate of point II). 4Immediately after the hammer blow is delivered, the pressure drops to zero.

The time consumed by the entire cycle, as represented by the abscissa of point I0 or point 9 may be very short, of the order of a fraction of a second.

The apparatus whereby this cycle may be accomplished is illustrated somewhat diagrammatically in Figs. 3, 4 and 6.

'I'he electrode structure 3 in this instance is shown as carried by a member Il of cylindrical form, guided for axial movement in an aperture I2. This aperture I2 is located in the hub I3 of a cover member I4.

Provisions are made for exerting a gradually increasing pressure upon the member II for transmission 'of -that pressure to the electrode structure 3. For this purpose use is made of a compression spring I6 housed in a barrel I1.

right hand end of thesleeve I9. This cylinder 20 has an integral flange 2I over which telescopes the right hand end of the barrel II and to which the barrel I1 may be fastened. The cylinder 20 may also be pmvided with an internally threaded integral collar 22 for the accommodation of a body member 23 which incorporates the control apparatus, such as valves and their operating mechanism. For the present it is suiilcient t0 note that the cylinder 20 is so arranged that it may accommodate a movable piston' 24 located within the cylinder.

Piston 24, upon being urged toward the right under the inuence of expanding compressed air, is arranged to strike the end 25 of an impact sustaining member 26. This impact sustaining member 26 is guided for free sliding -movement in the right hand end of the cylinder 20. It is joined as by the aid of its end flange 21 to the right hand end of the sleeve I9. This joining may be accomplished for example by an annular welded bead 28.

Movement of the piston 24 toward the right ultimately causes engagement of the piston with the left hand surface of the extension 25; and thereafter the sleeve I9 is carried toward the right, causing compression of the spring I6 and a driving force upon the electrode 3.

The arrangement is furthermore such that ii desired, a violent hammer blow may be exerted upon the structure carrying the electrode 3 at the completion of the piston stroke. Thus for example the member II may carry an anvil member 29. Thisanvii 29 may be attached to the left hand end of member II as by the aid of the threaded extension 3U. The anvil 29 is purposely made easily detachable from member I I, so that different anvils of varying lengths may be substituted. In this way that point during the cycle of travel of the piston 24 when the hammer blow is delivered, can be determined.

As heretofore stated, the gradually increasing pressure upon the electrode 3, is so arranged that at some intermediate interval of the operative movement of the piston 24 an electric current can be passed through pieces I and 2 for heating the area to be welded. The period of heating begins a short time afterthe spring I8 is beginning to'compress, and the heating eiiect is made -to last until almost the end of the pres- The cover member I4 has a flange telescoping within the right hand end of the barrel I1, and thus serves as a cap or cover for the right hand end of barrel I'I. The barrel I'I and the cover member I4 may be appropriately joined together.

One end of the compression spring I6 is seated on the flange I5, shown in this instance as formed integrally with the member II. The left hand end of the spring I6 abuts a :lange I9 4formed on an axially movable hollow sleeve I9. This sleeve I9 vis located within the barrel I1,

and may be coaxial therewith. It is arranged to be driven toward the right for compressing the spring I6, and thereby increasing the pressure acting upon the member II.

For causing motion of the sleeve I9,A use is made of a. cylinder and piston mechanism adapted to operate for example by the aid of compressed air. 'I'hus for example there is a stationary cylinder 20 reaching nearly to the sure exertion cycle. As the pressure is increased, there is a corresponding variation in current flow; and since the resistance is greatest between the interfaces of pieces I and 2, the heating effect is quite well confined to the place where these two pieces are in contact. and under the pressure exerted by the electrode 9.

There is diagrammatically illustrated in Fig. 3 one manner in which the control of the electric heating circuit may be effected. For example, a bar or rod 3| may extend between the cover I4 and ange 2|. This bar or rod passes through a sleeve 32 attached to the ilange Il of member II. Similarly the flange Il oi' the tubular member I9 carries a conducting sleeve 3l. The sleeve 32 carries a spring contact linger I4. This contact tlnger is insulated from the sleeve 92 and is in the path of movement of the conducting sleeve 33. Movement of the sleeve I9 toward. lthe right'to compress spring Il causes movement of the conducting member 33 toward the right and ultimately contact is madeiwith the spring nger I4.- When this occurs, a control circuit'is completed through the grounded connection 39, connection 40, contact iinger 34 and sleeve 33, for causing a relay or time delay energy, the interval of heating through the electrode structure 3 is sufficient to cause the formation of a plastic or molten pool 4 (Fig. 1) between the pieces I and 2. The period of heating is stopped prior to the ultimate maximum compression of spring I6 so as to'cause pressure to be applied during the period of congealing of the plastic or molten material. Also, by permitting the hammer blow to be struck upon the anvil 28 by the flange 21 of the member 26, the last step of applying a forging blow may be accomplished.

The control mechanism for the piston 24 in cylinder 20 is illustrated somewhat diagrammatically in Figs. 3 and 6, andit is shown in still more diagrammatic form in- Fig. 4.

The body 23 is provided at one end with an annular port 4I communicating with the left hand or open end of the cylinder 20. This port 4I is in communication, as by the aid of aperture 42, with an inlet chamber 43. The aperture 42 extends through a wall 44 formed adjacent the right hand portion of the body 23, for the accommodation of various passages or ports for purposes hereinafter to be described..

The inlet space 43 is defined by wall 45 forming a iiat valve seat 46. In the inactive or quiescent position, this inlet space 43 is closed against the entry of air under pressure, by an appropriate valve closure structure.

The closure member for the valve seat 46 is shown in this instance as a yielding disk 41, having its edge in contact with the seat 46. The closure member 41 is mounted in any appropriate manner upon the end of a movable valve operating piston member 48. This piston member is slidable in appropriate guiding cylinder walls 48 formed in the body 23. In the inactive position, air under pressure is conducted to the lower side of the piston structure 48 to keep the valve` closure 41 seated. However, byappropriate mechanism this piston 48 may be moved downwardly so as to connect the inlet chamber 43 with a reservoir space 50. This reservoir space is adapted to be filled with compressed air at a denite pressure.

Accordingly when the valve closure 41 moves downwardly away from its seat, the potential energy of the compressed air in space 50 is effective through space 43, aperture 42 and port 4I, to urge the piston 24 toward the right, and thereby to convert the potential energy into kinetic energy of the moving piston 24.

The reservoir 50 is shown in this instance as being deiined by a wall I and by a guiding hub 86 extending axially to the piston 24.

The passage of air into the space 50 and into the lower side of the piston 48 which carries the closure member 41, is effected through a valve port 52. This valve port may be formed within a valve member 53 threaded in a wall 54 integral with the body member 23. In the inactive position this valve port 52 in opened but may be closed by a valve closure 55.

Air under pressure is led to a space 56 formed in body 23, and leading to the right hand side of the port 452, as by the aid of a conduit 51. This conduit 51 may be connected, as by flexible hose, to any appropriate source of air pressure, such as an air compressor system or tank. The air passes from space 56 through port 52 and into a space 58. From this space there are two paths in parallel for the air; one path is by way of the connection 59 to a pressure reducer valve 60. From the pressure reducer valve there is a connection 6I leading directly to the reservoir 50. The air in reservoir 50 is thus kept at a desired pressure prior to the opening of the valve closure 41.

Air is also permitted to pass from space 58 to a passage 62 formed in the wall of member 23, as well as in the wall 44. This passageway conducts air to the space 63 beneath the piston 48.

In order that this space be maintained closed, a cover member 64 is provided, attached to the body 23.

By simultaneous manipulation of valve 55 and piston 48, the flow of air as just described can be interrupted, and the reservoir 50 can be opened. To open the reservoir, the space 63' is exhausted, and the valve closure 41 then moved to open position. Thereupon the piston 24 is urged by air pressure inwardly of the cylinder 20. A diagrammatic representation of mechanism to accomplish this result includes a manually operated lever 65. This lever is shown as pivoted near the upper end of a handle 66 attached to the cover member 61 for the left hand end of the body 23'. Movement of the lever 65 in a counterclockwise direction causes substantially simultaneous opening of the valve closure 41 and closing of the valve port 52. For this purpose the valve 55 may be provided with a stem 68 projecting through the cover 61. This stem 68 may be appropriately arranged to slide through a suitable packing gland structure 69. Its left hand end may terminate in an enlarged head 10 adapted to be contacted by an actuator This actuator 1I is pivotally mounted intermediate the lever 65. Acoil spring 12 may if desired be interposed between the cover 61 and the head 16 for normally urging the valve stem 68 toward open position. The actuator 1I is caused to depress the stem 68 and closes the valve 52. Simultaneously the lower end of lever 65 engages one arm of a bell crank lever 13. This bell crank lever may be appropriately pivoted on the body 23. The short arm 14 of the lever 13 is arranged to push a push rod 15 projecting through the cover 64.

F01 this purpose the push rod 15 may be appropriately guided and sealed against escape of air, in cover 64. The inner end of the push rod 15 is arranged to break a toggle mechanism connected between the cover'64'and the piston 48. This toggle mechanism includes a clevis 16 which also serves to hold the closure disk 41 in place on the piston 48. The toggle also includes a clevis 11 attached to the cover 64. The integral stud 18 attached to the clevis 11 passes through the cover 64 and may serve as a fastening means for the clevis, as by the aid of the nut 19. A threaded cap may be provided for covering the projecting stud 18.

Joining the clevises 16 and 11 are a pair cf toggle links 8l and 82. Normally the air pressure in chamber 63 serves to hold the toggle mechanism in substantially the straight position illustrated in Fig. 3. A tension spring 83 may be utilized to assist in urging the toggle mechanism to this position. However, when the bell crank lever 13 is rotated in a counterclockwise direction the push rod 1,5 operates on link 82 ,and breaks the toggle, depressing the closure disk 41 to open position. The pressure of the air escaping from the reservoir 50 past the disk 41 keeps the valve open until the completion of the welding cycle.

In order to ensure that air can exhaust from the space 63 so that there may be no interference with the opening of the valve closure, an exhaust passage 84 is provided, leading from the space 63. This exhaust passage leads -into a space 85, connected to atmosphere. This space 35 is formed between the walls 5| and 50. It is controlled by an exhaust valve closure S1 cooperating with a valve port forming member 88 in wall 54. The stern 89 for closure 8l is guided through the cover member 61 in the same manner as stem 6,8 for valve 52. It is likewise adapted to be depressed by the actuator 1| upon movement toward the right of the control lever 65. Accordingly when control lever 65 is moved in a counterclockwise direction, the exhaust Valve 81 opens, and air from space 63 n is exhausted through the exhaust passage 90.

Upon release of the lever 65, the valve stem springs such as spring 12, operate on actuator 1| to return the mechanism to the position shown in Fig. 3. In this position air can again enter into the reservoir 50 past valve 52, and through the regulator valve 60. Air can also pass through passageway 62 to the lower side of the piston 48, urging the closure 41 to its closed position, and straightening the toggle mechanism.

As thus far described, the piston 24 at the conclusion of the cycle might be retained in its extreme right hand position in cylinder 20, Provisions are made, however, for returning the piston 24 to the starting position illustrated, upon release of lever 85. For this purpose, automatic mechanism is provided operating by air pressure, to move the piston 24 toward the left.

The mechanism for accomplishing this purpose includes a stem 9| which projects through a cylinder sleeve 92 fastened inside of the hub 80. This stem 9| is detachably connected to the piston 24. For this purpose the piston 24 has an axial aperture 93 in which the rounded end of the stem 9| may project. The stem 9| furthermore has a groove 94 formed by slanting walls and adapted to cooperate with a plurality of spring pressed balls 95. These balls 95 are guided in appropriate radial apertures in the piston 24, and are urged inwardly into groove 94 for detachably connecting the stem 9| to piston 24. This is accom-l plished by the aid of springs 96. These springs are held in compressed position by the headless screws 91 threaded into the outer portions of end radial apertures.

Upon release of air from reservoir 50 through the port 4| to move the piston 24 toward the right, this piston 24 moves sufliciently violently so as to release the balls 95 and piston 24 is free to travel without restraint in the cylinder 20.

However, the stem 9| is guided for axial movement and is intended to follow the piston 24 and to be urged into engagement with the piston.

For this purpose the stem 9| is shown as guided through a packing gland structure 90 in a boss 99 formed concentrically with the hub 80. At its left hand end the stem 9| carries an auxiliary piston structure |00 adapted to slide within the cylinder 92. The piston |00 is adapted to be urged toward the right to follow the piston 24 by air pressure in space |0|. Compressed air can enter space |0| past a valve closure |02 of similar construction to the valves already described. This valve closure |02 operates against a seat formed in valve member |03 and is normally closed in the inactive position. However, when the actuaator 1| depresses the stem |04 of closure |02, compressed air is free to pass into space l0 I, and the piston |00 moves toward the right, This occurs substantially simultaneously with the closing of valve closure 52 and the opening of the valve closure 41. Accordingly, the stem 9| is urged downwardly by 'air pressure to be reengaged by the :balls 95. The right hand end of the stem 9| is rounded in order to ensure that it can act as a cam to spread the balls 95. Furthermore, the aperture 93 in piston 24 has a ilared portion I4 to assist in guiding the rounded end of stem 9| into the aperture.

Upon completion of the welding operation, the actuator 1| may be released. This causes the entry of air within the cylinder 92 in the space to the right of the piston |00 to move the piston |00 to the extreme left hand position indicated. For this purpose the cylinder 92 has one or more openings |05 communicating with the air passage 62. Accordingly when passage 62 is again connected to the inlet conduit 51, past the closure 55, the piston |00 and its stem 9| are urged toward the left, and the main piston 24 is carried along with the stem 9|.

Exhaust passages are also provided for exhausting the space from one or the other side of the auxiliary piston |00. Thus in the inactive position shown in Fig. 3, the space |0| is shown as vented past the exhaust valve closure |00 which is open when the apparatus is inactive. This valve closure cooperates with valve structure |01, and is urged to its seat when the lever 55 is moved to initiate the welding cycle. Since valve closure |02 simultaneously opens, air pressure is then eiective to urge the auxiliary piston |00 toward the right.

Similarly, when the lever 65 is moved to initiate the welding cycle, the exhaust rvalve closure 01 is opened, and this serves simultaneously to exhaust air from the right hand side of the auxiliary piston |00, permitting free movement of this piston. 'I'his is effective through the ports |05, and passage 02. As soon as lever 55 is released, the exhaust valve |01 opens, and exhaust valve 81 is closed; and at the same time, compressed air passes into cylinder 92 to move the piston |40 toward the left.

Provisions may also be made to ensure that the air in cylinder 20 on the left hand side of the piston 24 will be exhausted when the lever 65 is releasedV at the conclusion of the welding cycle, thereby removing any resistance to the return of the piston. For this purpose, as illustrated dia-- grammatically in Fig. 4, there is provided a passageway |08 leading from the space 43 to'the exhaust'valve |01. This passageway may be controlled by a ballcheck valve diagrammatically illustrated at |09, which permits passage ot air only outwardly from the space 43.

The operation of the welding mechanism may now be summarized. In the position indicated in Fig. 3, the reservoir 50 is illled with air and is kept sealed against escape past the valve closure work, means forming a pneumatic l ausw pressure is effective against o! the auxiliary'plston |00,

41. Pinthermore,air thevriht hand side 4l is depressed to the open position by the aid ot push rod I5 operating on the toggle mechanism. At the same time air is exhausted from the space 0l and air is permittedV to enter the space |0|. Accordingly air is efl'ective immediately to urge the piston 24 by compressed air passing through port 4|, to cause piston 24 to strike the extension 25. Thereafter the kinetic energy of the piston 24, imparted to it by the expanding air from reservoir 50, is converted into the work of cornpressing spring IG. 'I'he auxiliary piston |00 and stem 0| follow this movement. For this condition, valve closures 55 and |06 are urged to the closed position, shutting oil' air supply to the reservoir 50 as well as to the lower side of the valve piston 40 and the right hand side of the auxiliary piston |00. The valve closure |06 is also urged to closed position, and valve closure |02 is urged to open position, supplying air to the left hand side of the auxiliary piston |00.

Upon release of the lever 65, the valve closure 4l is returned to the position illustrated in Figs. 3, 4 and 6. 'I'he reservoir 50 promptly becomes filled with compressed air at the desired pressure, and the auxiliary piston |00 is moved toward the left to return main piston 24 to the inactive position indicated. Air is also passed into space 63 to cause valve closure 4l to seal the reservoir 50.

In the travel of the piston 24, the extension 25 is engaged and the spring i0 is gradually compressed. At the conclusion of the stroke the anvil 20 may be struck, if desired, to complete the welding operation by forging. At an intermediate point, the circuit for control of the time delay switch is completed and heating current is permitted to pass for a. short interval.

It is not essential that the motive power be compressed air. It is feasible instead to provide an electromagnet coil 0 (Fig. 5) for operating upon the magnetic piston to effect the same result. A similar structure may be used to retract trolling the current to of an operating member H3. In other respects the apparatus may be similar to that described, switches in general being utilized in place` o! valves.

-while the force Y whereby the force has reached a definite amount,

the coil H0, as by the aid 1. In a welder vof the character described, a

resilient member for exerting pressure upon the cylinder, a piston therein, and arranged near the end of its travel to transmit a force to said member, means for initiating the movement of the piston by pneumatic pressure, and means predetermining the quantity of air that is used in one cycle of operation of the piston.

2. In a welder ot the character described,4 a resilient member for exerting pressure upon Athe work. m forming a pneumatic cylinder. a pisand arranged near the end of its travel to transmit a torce to said member, means for initiating the movement of the piston by pneumatic pressure, and means forming a limited storage space for predetermining the quantity oi' air that is used in one cycle of operational the `for limited free A 5 A3. 'In a Welder, a cylinder, a piston arrange for limited treeemoyement-in the cylinder, means forming a reservoir for compressed air, a member for exerting pressure upon work to be welded, means inthe path of movement of the piston and normally spaced from said piston, for utilizing the momentum of the piston to operate said member, means for connecting the cylinder to the reservoir for urging the piston into cooperative relation with said means inthe path of piston movement, and a circuit controller operated in response to movement of the meansl operating the pressure exerting member, tor passing a heating current to the work for a predetermined interval.

4. In a Welder, a member adapted to engage the work, means movable toward said member for creating a rapidly increasing force urging saidmember against the work, and means operated by said force producing means for passing a heating current to the work for an interval is increasing, said interval beginning when the force producing means has reached adeilnite position with. respect to said member,

and continuing for a predetermined interval.

5. In a welder, a member adapted to engage the work, a movable member, resilient means interposed between said members whereby movement oi' the movable member will cause the irst mentioned member ing pressure, means to move the movable member, means passing a heating current to the work, and control means for initiating flow of said current operated by arrival ot the movable member at a point intermediate the initial and nal positions of said movable member, said control means also including means for terminating said current iiow independently ot the position of the movable member. l

6. Ina Welder, a cylinder, a piston arranged movement in the cylinder,` a source of compressed air, means connecting said source and said cylinder, a member for engaging the work, a movable member in the path of move-v ment of the piston and spaced near the end of said movement, whereby momentum of the piston to open.

8. In a Welder, a main cylinder, a main piston lin the cy to its initial position, a cylinder for said auxiliary to engage the work with a varytons, a source of compressed air, means for admitting air simultaneously to both cylinders for causing the pistons to move in the same direction, means for admitting air to the cylinder of the auxiliary piston to return the pistons` to their initial positions, and .exhaust valves for thecylinders.

9. In a Welder, a main cylinder, a main piston in the cylinder, a member for engaging the work, means whereby movement of the main piston in one direction urges said member against the work, an auxiliary piston for returning the main piston to its initial position, a cylinder for said auxiliary piston, a releasable connection between the pistons, a source of compressed air, means forming a connection to each of said cylinders for admitting air to cause the pistons to move in the same direction, a Valvecontrolling the connection to the auxiliary cylinder, a diierential valve controlling the connection to the main cylinder, a guide cylinder for said differential valve, means admitting pressure to said guide cylinder to urge the differential valve to closed position, linkage for maintaining said differential valve closed, and

means for substantially simultaneously opening the ilrst mentioned valve, to admit air to the auxiliary cylinder permitting discharge of air from the guide cylinder and releasing said linkage, to

cause the differential valve to open.

10. In a Welder, means forming an electrode for engaging the work to be welded, means for continuously applying a steadily increasing pressure on said electrode, and means for passing heating current to the electrode for a predetermined period beginning substantiaily above the initial pressure and ending substantially below the maximum pressure, including a time delay means. 

